tensility
简明释义
n. 张力;伸长性;伸力
英英释义
The quality or state of being capable of being stretched or extended; elasticity. | 能够被拉伸或延展的性质或状态;弹性。 |
单词用法
高延展性 | |
低延展性 | |
具有高延展性的材料 | |
延展性测试 |
同义词
反义词
| 刚性 | The rigidity of the material makes it unsuitable for flexible applications. | 该材料的刚性使其不适合灵活应用。 | |
| 僵硬 | Excessive stiffness in a structure can lead to brittleness and failure. | 结构过度僵硬可能导致脆性和失效。 |
例句
1.Membrane effect of steel is evolved from the technology of stressed skin in steel structure, of which the characteristic is the sufficient utilization of the effect of tensility-resist.
钢板薄膜效应是从钢结构的受力蒙皮技术中拓展而来的,其主要特点是充分利用钢板在面内的抗剪和抗拉效应。
2.Tensility structures, cable antenna and inflatable antenna are all flexible structures.
索膜结构,索网天线和充气反射器都是柔性结构。
3.ObjectiveTo study the method decreasing muscle tensility of upper limb and improving the function of disabled limb and hand on the spastic period in children with hemiplegia.
目的探讨偏瘫儿童痉挛期在临床康复训练中降低患侧上肢肌张力,促进患肢及手的功能发育的方法。
4.The optimized reposition balance method for force-finding analysis usually is employed to accurately evaluate the self-balance prestress of tensility structures.
对索膜结构找力分析的优化复位平衡法,能够对给定的拓扑曲面求解获得精确的自平衡预应力分布。
5.The Conformation Theories of Tensility Structures and the Structure Analysis of Flexible Antennae;
脊椎状构造,结构严密象脊骨结构的环节分割;
6.The tensility beauty of literary language is embodied in image, connotation, ambiguity, vacancy and so on.
文学语言的张力美具体体现在形象、含蓄、模糊、空白等几个主要特征上。
7.It introduces the right discrimination method of frame short column in the high-rise building and brief describes some effective section forms of improving the tensility of frame column.
介绍了高层建筑框架短柱的正确判别方法,简述了几种有效提高框架柱延性的截面形式,提出短柱的抗震构造措施,以提高短柱的承载力和延性,改善短柱的抗震性能。
8.When designing bridges, engineers must consider the tensility of the materials to ensure safety.
在设计桥梁时,工程师必须考虑材料的延展性以确保安全。
9.The engineer tested the material for its tensility, which is crucial for ensuring it can withstand heavy loads.
工程师测试了材料的延展性,这对确保其能够承受重载至关重要。
10.In textiles, the tensility of fibers determines their durability and strength.
在纺织品中,纤维的延展性决定了它们的耐用性和强度。
11.The tensility of the rubber used in tires affects their performance on the road.
用于轮胎的橡胶的延展性影响其在道路上的性能。
12.The tensility of the metal wire allowed it to be stretched without breaking.
金属线的延展性使其能够被拉伸而不易断裂。
作文
Tensility is a term that refers to the ability of a material to withstand tension or stretching forces without breaking. This property is crucial in various applications, particularly in engineering and materials science. Understanding the concept of Tensility (拉伸性) allows us to appreciate how different materials behave under stress and how they can be utilized in practical scenarios.For instance, when designing structures such as bridges or buildings, engineers must consider the Tensility (拉伸性) of the materials they choose. Steel, known for its high Tensility (拉伸性), is often used in construction because it can absorb significant stress before failing. This characteristic ensures that structures remain safe and stable, even under heavy loads or adverse weather conditions.In contrast, materials with low Tensility (拉伸性), like certain types of ceramics, may crack or shatter under tension. This understanding is vital for architects and builders, who must select appropriate materials based on the specific demands of their projects. The ability to predict how a material will react under tension can mean the difference between a successful design and a catastrophic failure.Moreover, Tensility (拉伸性) plays a significant role in the development of textiles. Fabrics that are designed for clothing or industrial use must possess adequate Tensility (拉伸性) to ensure they can withstand everyday wear and tear. For example, nylon and spandex are popular choices for activewear due to their excellent Tensility (拉伸性), allowing them to stretch and return to their original shape without losing integrity.The importance of Tensility (拉伸性) extends beyond just physical materials; it also has applications in the biological sciences. For example, tendons and ligaments in the human body exhibit remarkable Tensility (拉伸性), enabling them to connect muscles to bones and facilitate movement. Understanding how these biological tissues maintain their strength and flexibility can inform medical practices and the development of prosthetics or tissue engineering.In conclusion, Tensility (拉伸性) is a fundamental property that influences various fields, from engineering to biology. Recognizing the significance of this term helps us understand the behavior of materials and their applications in real-world scenarios. Whether constructing a skyscraper, designing athletic wear, or studying human anatomy, the concept of Tensility (拉伸性) remains essential in ensuring functionality and safety. As we continue to innovate and develop new materials, the study of Tensility (拉伸性) will undoubtedly play a critical role in shaping the future of technology and design.
拉伸性是指材料在不破裂的情况下承受拉伸或拉力的能力。这个特性在各种应用中至关重要,尤其是在工程和材料科学领域。理解Tensility(拉伸性)的概念使我们能够欣赏不同材料在应力下的行为,以及它们如何在实际场景中被利用。例如,在设计桥梁或建筑物等结构时,工程师必须考虑他们选择材料的Tensility(拉伸性)。钢材因其高Tensility(拉伸性)而常用于建筑,因为它可以在失败之前吸收显著的压力。这一特性确保了结构在重负荷或恶劣天气条件下仍然安全稳定。相反,某些类型的陶瓷等低Tensility(拉伸性)材料在拉伸下可能会开裂或破碎。这种理解对建筑师和施工人员至关重要,他们必须根据项目的具体需求选择合适的材料。预测材料在张力下的反应能力可能意味着设计成功与灾难性失败之间的区别。此外,Tensility(拉伸性)在纺织品的开发中也起着重要作用。为服装或工业用途设计的面料必须具备足够的Tensility(拉伸性),以确保它们能够承受日常磨损。例如,尼龙和氨纶因其出色的Tensility(拉伸性)而成为运动服的热门选择,因为它们可以拉伸并恢复到原始形状而不失去完整性。Tensility(拉伸性)的重要性不仅限于物理材料;它在生物科学中也有应用。例如,人体中的肌腱和韧带表现出卓越的Tensility(拉伸性),使它们能够将肌肉连接到骨骼并促进运动。理解这些生物组织如何保持强度和灵活性可以为医疗实践和假肢或组织工程的发展提供信息。总之,Tensility(拉伸性)是一种基本特性,影响着多个领域,从工程到生物学。认识到这个术语的重要性有助于我们理解材料的行为及其在现实场景中的应用。无论是建造摩天大楼、设计运动服还是研究人体解剖,Tensility(拉伸性)的概念在确保功能性和安全性方面始终是必不可少的。随着我们继续创新和开发新材料,Tensility(拉伸性)的研究无疑将在塑造未来技术和设计中发挥关键作用。
